EC:3.5.4.4 - FACTA Search

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Query: EC:3.5.4.4 (adenosine deaminase)
5,136 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The biochemical mechanisms by which a genetically determined deficiency of adenosine deaminase leads to immunodeficiency are still poorly understood and prompted this study. We have examined the effects of the adenosine deaminase inhibitor erythro-9-(2-hydroxy-3-nonyl) adenine hydrochloride (EHNA) upon the response of human peripheral blood mononuclear cells to the mitogen concanavalin A (Con A). Cells isolated from normal volunteers were incubated in microtiter plates in the presence of various inhibitors, and the incorporation of tritrated thymidine or leucine into macromolecular material was measured after 64 h. EHNA at a concentration of 0.3 muM, which inhibited 90% of the adenosine deaminase (ADA) activity in a mononuclear preparation, impaired the incorporation of tritrated leucine into protein; 100 muM EHNA was the minimal concentration that inhibited thymidine uptake. The addition of 15 muM adenosine or 10 muM cyclic AMP to Con A-stimulated lymphocytes inhibited leucine uptake, while millimolar concentrations were required to inhibit thymidine uptake. Lower doses of adenosine and cyclic AMP stimulated thymidine incorporation. The inhibition of thymidine uptake observed with millimolar concentrations of adenosine was independent of the type of mitogen (pokeweed or Con A), the concentration of mitogen, or the medium used, but could be increased if the cells were cultured in a serum with reduced levels of adenosine deaminase. Washout experiments failed to demonstrate a critical period early in immune induction during which adenosine exerted its inhibitory effects. Noninhibitory doses of EHNA potentiated the effects of adenosine and cyclic AMP on leucine and thymidine uptake. EHNA at a concentration of 50 muM also potentiated the inhibitory effects on thymidine uptake of dibutyryl cyclic AMP, butyric acid, norepinephrine, and isoproterenol, but not theophylline. When mitogenesis was assayed by leucine incorporations, no synergy between EHNA and these compounds was apparent. Uridine relieved to some extent the inhibition of blastogenesis produced by adenosine and cyclic AMP, but not by dibutyryl cyclic AMP, norepinephreine, isoproterenol, or theophylline. Neither uridine alone nor uridine plus adenosine protected lymphocytes from the inhibitory effects of EHNA.
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PMID:Effect of adenosine deaminase inhibition upon human lymphocyte blastogenesis. 17 77

Micromolar deoxyadenosine inhibits leucine uptake during the 1st day of proliferation in mitogen-stimulated lymphocytes if adenosine deaminase is inhibited. This inhibition occurs before DNA synthesis begins, suggesting that deoxyadenosine can affect mitogenesis by mechanisms that do not involve ribonucleotide reductase inhibition. If deoxyadenosine addition to mitogen-stimulated lymphocytes is delayed to the 2nd or 3rd day post-stimulation, inhibition of proliferation is markedly reduced. Although the time dependence of deoxyadenosine toxicity resembles that of adenosine, these compounds appear to inhibit early protein synthesis by different mechanisms: 1) deoxycoformycin markedly potentiates deoxyadenosine but not adenosine; 2) deoxycytidine and thymidine reverse deoxyadenosine toxicity but do not alter adenosine toxicity.
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PMID:The effect of nucleosides and deoxycoformycin on adenosine and deoxyadenosine inhibition of human lymphocyte activation. 31 74

Although commonly used to control a variety of inflammatory diseases, the mechanism of action of a low dose of methotrexate remains a mystery. Methotrexate accumulates intracellularly where it may interfere with purine metabolism. Therefore, we determined whether a 48-hr pretreatment with methotrexate affected adenosine release from [14C]adenine-labeled human fibroblasts and umbilical vein endothelial cells. Methotrexate significantly increased adenosine release by fibroblasts from 4 +/- 1% to 31 +/- 6% of total purine released (EC50, 1 nM) and by endothelial cells from 24 +/- 4% to 42 +/- 7%. Methotrexate-enhanced adenosine release from fibroblasts was further increased to 51 +/- 4% (EC50, 6 nM) and from endothelial cells was increased to 58 +/- 5% of total purine released by exposure to stimulated (fMet-Leu-Phe at 0.1 microM) neutrophils. The effect of methotrexate on adenosine release was not due to cytotoxicity since cells treated with maximal concentrations of methotrexate took up [14C]adenine and released 14C-labeled purine (a measure of cell injury) in a manner identical to control cells. Methotrexate treatment of fibroblasts dramatically inhibited adherence to fibroblasts by both unstimulated neutrophils (IC50, 9 nM) and stimulated neutrophils (IC50, 13 nM). Methotrexate treatment inhibited neutrophil adherence by enhancing adenosine release from fibroblasts since digestion of extracellular adenosine by added adenosine deaminase completely abrogated the effect of methotrexate on neutrophil adherence without, itself, affecting adherence. One hypothesis that explains the effect of methotrexate on adenosine release is that, by inhibition of 5-aminoimidazole-4-carboxamide ribonucleotide (AICAR) transformylase, methotrexate induces the accumulation of AICAR, the nucleoside precursor of which (5-aminoimidazole-4-carboxamide ribonucleoside referred to hereafter as acadesine) has previously been shown to cause adenosine release from ischemic cardiac tissue. We found that acadesine also promotes adenosine release from and inhibits neutrophil adherence to connective tissue cells. The observation that the antiinflammatory actions of methotrexate are due to the capacity of methotrexate to induce adenosine release may form the basis for the development of an additional class of antiinflammatory drugs.
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PMID:Methotrexate inhibits neutrophil function by stimulating adenosine release from connective tissue cells. 200 82

We have previously characterized mutant adenosine deaminase (ADA; adenosine aminohydrolase, EC 3.5.4.4) enzymes in seven children with partial ADA deficiency. Six children shared common origins, suggesting a common progenitor. However, we found evidence for multiple phenotypically different mutant enzymes. We hypothesized that many of the mutations would be at CpG dinucleotides, hot spots at which spontaneous deamination of 5-methylcytosine results in C to T or G to A transitions. Digestion of DNA from these children with Msp I and Taq I, enzymes recognizing CpG dinucleotides, identified three different mutations, each correlating with expression of a different mutant enzyme. Sequencing of cDNA clones and genomic DNA amplified by polymerase chain reaction confirmed the presence of C to T or G to A transitions at CpG dinucleotides (C226 to T, G446 to A, and C821 to T, resulting in Arg76 to Trp, Arg149 to Gln, and Pro274 to Leu). A "null" mutation, also found in two ADA-deficient severe combined immunodeficient children, was serendipitously detected as gain of a site for Msp I. Simultaneous loss of a site for Bal I defined the precise base substitution (T320 to C, Leu107 to Pro), confirmed by sequence analysis. To determine the true frequency of hot spot mutation in these children, consecutively ascertained through a newborn screening program, we sequenced cDNA from the remaining alleles. Two others were hot spot mutations (C631 to T and G643 to A, resulting in Arg211 to Cys and Ala215 to Thr), each again resulting in expression of a phenotypically different mutant enzyme. Only one additional mutation (previously identified by us) is not in a hot spot. These seven mutations account for all 14 chromosomes in these children. There is thus a very high frequency of hot spot mutations in partial ADA deficiency. Most of these children carry two different mutant alleles. We were able to correlate genotype and phenotype and to dissect the activity of individual mutant alleles.
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PMID:Hot spot mutations in adenosine deaminase deficiency. 216 47

Neplanocin A is a naturally occurring carbocyclic analog of adenosine which contains a cyclopentene moiety in place of ribose and has demonstrated antitumor and antimicrobial activity. This compound was highly toxic to Chinese hamster ovary (CHO) cells; the approximate minimum inhibitory concentration of neplanocin A for inhibition of clone formation was 0.1 microM. The toxicity of the agent was greatly reduced by prior treatment with adenosine deaminase. [3H]Uridine incorporation into perchloric acid insoluble material in growing cells was inhibited by neplanocin A more dramatically than that of [3H]thymidine or [3H]leucine. Treatment with the drug resulted in a marked depression of ATP pool levels. High pressure liquid chromatographic analysis of cellular nucleotide pools from cells treated with neplanocin A revealed the formation of an apparent drug metabolite (NpcTP) that eluted in the triphosphate region of the chromatographic profile. Treatment of NpcTP with alkaline phosphatase produced a nucleoside with properties similar to neplanocin A. An adenosine-kinase-deficient cell line formed little, if any, NpcTP but demonstrated only slight resistance to the agent. These observations suggest that neplanocin A was efficiently metabolized to the triphosphate level but that this metabolite was responsible for only a fraction of the observed toxicity.
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PMID:Metabolism and action of neplanocin A in Chinese hamster ovary cells. 240 84

The distribution and morphology of adenosine deaminase, substance P, leucine-enkephalin, corticotropin-releasing factor, and calcitonin gene-related peptidelike immunoreactive cells and fibers throughout the superior colliculus of the rat were examined by means of the unlabelled-antibody peroxidase-antiperoxidase method. Adenosine deaminase immunoreactive cells were found in the stratum opticum and lower stratum griseum superficiale; substance P immunoreactive cells were localized to the upper stratum griseum superficiale, and calcitonin gene-related peptide immunolabelled neurons were situated in deeper strata. Substance P, leucine-enkephalin, and calcitonin gene-related peptide immunoreactive fibers were distributed similarly in their lamination and in their patchlike organization. Corticotropin-releasing factor immunoreactive fibers were observed evenly throughout all the strata and were fewer in the stratum griseum superficiale. These findings suggest that, as in afferent modules and segregated efferents of the mammalian superior colliculus, the cells and fibers containing neuroactive substances and neuroactive substance-related enzymes also show a segregated and laminar distribution.
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PMID:Laminar and segregated distribution of immunoreactivities for some neuropeptides and adenosine deaminase in the superior colliculus of the rat. 246 26

The metabolism and metabolic effects of 2-azahypoxanthine and 2-azaadenosine were studied to elucidate the biochemical basis for their known cytotoxicities. 2-Azaadenosine is a known substrate for adenosine kinase. That 2-azahypoxanthine is a substrate for hypoxanthine (guanine) phosphoribosyltransferase is shown by the observations that, in cell-free fractions from HEp-2 cells supplemented with 5-phosphoribosyl-1-pyrophosphate, 2-azahypoxanthine inhibited the conversion of hypoxanthine to IMP but not the conversion of adenine to AMP, and hypoxanthine, but not adenine, inhibited the conversion of 2-azahypoxanthine to 2-azaIMP. [8-14C]2-Azahypoxanthine was synthesized from [8-14C]hypoxanthine via [2-14C]-4-amino-5-imidazolecarboxamide. In HEp-2 cells in culture, the principal metabolite of [8-14C]-2-azahypoxanthine was 2-azaATP; there was no detectable 14C in deoxynucleotides or in DNA or RNA fractions. 2-Azaadenosine was much more toxic than 2-azahypoxanthine, and, when used in the presence of an adenosine deaminase inhibitor, 2'-deoxycoformycin, was converted in HEp-2 cells to 2-azaATP in amounts that exceeded those of ATP in control cells. The pool of ATP was reduced by as much as 75% as 2-azaATP accumulated. In a short-term experiment (4 hr), 2-azaadenosine selectively reduced the pools of adenine nucleotides, whereas 2-azahypoxanthine reduced the pools of guanine nucleotides selectively. Both 2-azahypoxanthine and 2-azaadenosine inhibited the incorporation of formate into purine nucleotides and were without effect on the conversion of thymidine and uridine to nucleotides. 2-Azahypoxanthine inhibited the incorporation of thymidine into macro-molecules but not that of uridine or leucine; 2-azaadenosine inhibited the incorporation of all three of these precursors non-selectively. 2-AzaIMP inhibited IMP dehydrogenase competitively with IMP (Ki = 66 microM). The difference in effects of 2-azahypoxanthine and 2-azaadenosine perhaps may be due to the production, from 2-azahypoxanthine but not from 2-azaadenosine + 2'-deoxycoformycin, of 2-azaIMP, which inhibits synthesis of guanine nucleotides and thereby results in inhibition of DNA synthesis. Specific sites of action for 2-azaadenosine are yet undefined.
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PMID:Metabolism and metabolic effects of 2-azahypoxanthine and 2-azaadenosine. 285 58

We have cloned and sequenced an adenosine deaminase (ADA) gene from a patient with severe combined immunodeficiency (SCID) caused by inherited ADA deficiency. Two point mutations were found, resulting in amino acid substitutions at positions 80 (Lys to Arg) and 304 (Leu to Arg) of the protein. Hybridization experiments with synthetic oligonucleotide probes showed that the determined mutations are present in both DNA and RNA from the ADA-SCID patient. In addition, wild-type sequences could be detected at the same positions, indicating a compound heterozygosity. Studies with ADA expression clones mutagenized in vitro showed that the mutation at position 304 is responsible for ADA inactivation.
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PMID:One adenosine deaminase allele in a patient with severe combined immunodeficiency contains a point mutation abolishing enzyme activity. 300 8

Addition of the chemotactic peptide, f-Met-Leu-Phe, to human monocytes induced a burst of superoxide release, which ceased after approximately 3 min. Diminished responsiveness to f-Met-Leu-Phe, but not to phorbol myristate acetate (PMA), was induced by 1- to 3-h storage at 0 degrees C or by 2 min in 40 microM adenosine (ADO). Reversal of the ADO block was achieved by addition of adenosine deaminase (ADA) as little as 15 sec before the f-Met-Leu-Phe stimulus; ADA had no effect when added poststimulus. The ADO experiments suggest that there are a minimum of two sequentially produced intermediates in the f-Met-Leu-Phe stimulus-response pathway. The first intermediate persists for less than 30 sec. The second, formation of which is stimulated by the first, persists for the duration of the response and is the target of ADO inhibition. The ADO target is apparently not protein kinase-C, since the response of inhibited cells to PMA was unimpaired. The maximal inhibition by adenosine of f-Met-Leu-Phe-induced superoxide generation was approximately 50%. It is possible that f-Met-Leu-Phe stimulates two pathways of NADPH activation, only one of which is inhibited by adenosine.
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PMID:Dynamics of chemotactic peptide-induced superoxide generation by human monocytes. 303 84

Human promyelocytic leukemia (HL-60) cells were used to begin to evaluate the role in hematopoiesis of inosine biosynthesis in the tRNA anticodon wobble position; a reaction involving the enzymatic insertion of performed hypoxanthine. Dimethyl sulfoxide (DMSO) and hypoxanthine were found to induce the differentiation of HL-60 cells in a synergistic manner, and the induced differentiation was independent of changes in the purine catabolic enzymes adenosine deaminase and purine nucleoside phosphorylase. The short-term exposure of HL-60 cells to DMSO plus hypoxanthine resulted in enhanced leucine incorporation, and a model is presented showing how the inosine modification reaction in tRNA may be involved. A means by which hypoxanthine insertion into tRNA may modulate the synthesis of regulatory proteins (e.g., lymphokines and cell surface receptors) is also outlined.
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PMID:Hematopoiesis and the inosine modification in transfer RNA. 392 6

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